Global pattern of earthquakes and seismic energy distributions: Insights for the mechanisms of plate tectonics
Author(s)
Language
English
Obiettivo Specifico
3.3. Geodinamica e struttura dell'interno della Terra
Status
Published
JCR Journal
JCR Journal
Peer review journal
Yes
Journal
Issue/vol(year)
/530-531(2012)
ISSN
0040-1951
Electronic ISSN
1879-3266
Publisher
Elsevier Science Limited
Pages (printed)
80-86
Date Issued
March 2012
Abstract
In this paper, we analyse the distributions of number of events (N) and seismic energy (E) on the Earth's surface and
along its radius as obtained from the global declustered catalogue of large independent events (M≥7.0), dissipating
about 95% of the Earth's elastic budget. The latitude distribution of the seismic event density is almost symmetric
with respect to the equator and the seismic energy flux distribution is bimodal; both have their medians near the
equator so that they are equally distributed in the two hemispheres. This symmetry with respect to the equator suggests
that the Earth's rotational dynamics contributes to modulate the long-term tectonic processes.
The distributions of number and energy of earthquakes versus depth are not uniform aswell: 76% of the total earthquakes
dissipates about 60% of the total energy in the first ~50 km; only 6% of events dissipates about 20% of the
total amount of energy in a narrow depth interval, at the lower boundary of the upper mantle (550–680 km).
Therefore, only the remaining 20% of energy is released along most of the depth extent of subduction zones
(50–550 km). Since the energetic release along slabs is a minor fraction of the total seismic budget, the role of
the slab pull appears as ancillary, if any, in driving plate tectonics. Moreover the concentration of seismic release
in the not yet subducted lithosphere suggests that the force moving the plates acts on the uppermost lithosphere
and contemporaneously all over the Earth's outer shell, again supporting a rotational/tidal modulation.
along its radius as obtained from the global declustered catalogue of large independent events (M≥7.0), dissipating
about 95% of the Earth's elastic budget. The latitude distribution of the seismic event density is almost symmetric
with respect to the equator and the seismic energy flux distribution is bimodal; both have their medians near the
equator so that they are equally distributed in the two hemispheres. This symmetry with respect to the equator suggests
that the Earth's rotational dynamics contributes to modulate the long-term tectonic processes.
The distributions of number and energy of earthquakes versus depth are not uniform aswell: 76% of the total earthquakes
dissipates about 60% of the total energy in the first ~50 km; only 6% of events dissipates about 20% of the
total amount of energy in a narrow depth interval, at the lower boundary of the upper mantle (550–680 km).
Therefore, only the remaining 20% of energy is released along most of the depth extent of subduction zones
(50–550 km). Since the energetic release along slabs is a minor fraction of the total seismic budget, the role of
the slab pull appears as ancillary, if any, in driving plate tectonics. Moreover the concentration of seismic release
in the not yet subducted lithosphere suggests that the force moving the plates acts on the uppermost lithosphere
and contemporaneously all over the Earth's outer shell, again supporting a rotational/tidal modulation.
References
Abe, K., Kanamori, H., 1979. Temporal variation of the activity of intermediate and deep
focus earthquakes. Journal of Geophysical Research 84, 3589–3595.
Amalvict,M., Legros,H., 1993. Stresses in the lithosphere induced by the Earth rotation. In:
Teisseyre, R. (Ed.), Physics and Evolution of the Earth's Interior, Volume 6: Dynamics
of the Earth's Evolution. PWNWarszawa and Elsevier, Amsterdam, pp. 348–349.
Bird, P., Kagan, Y.Y., Jackson, D.D., Shoenberg, F.P., Werner, M.J., 2009. Linear and nonlinear
relations between relative plate velocity and seismicity. Bulletin of the Seismological
Society of America 99 (6), 3097–3113.
Bormann, P., Saul, J., 2009. Earthquake magnitude. In: Meyers, R.A. (Ed.), Encyclopedia
on Complexity and Systems Science. Springer, Heidelberg.
Chouhan, R.K.S., Das, U.C., 1971. Preliminary report on global seismicity-frequency energy
distribution of earthquakes. Pure and Applied Geophysics 89 (1), 98–108.
Convers, J.A., Newman, A.V., 2011. Global evaluation of large earthquake energy from
1997 through mid-2010. Journal of Geophysical Research 116, B08304. doi:10.1029/
2010JB007928.
Crespi, M., Cuffaro, M., Doglioni, C., Giannone, F., Riguzzi, F., 2007. Space geodesy validation
of the global lithospheric flow. Geophysical Journal International 168,
491–506. doi:10.1111/j.1365-246X.2006.03226.
Denis, C., Schreider, A.A., Varga, P., Závoti, J., 2002. Despinning of the Earth rotation in the geological
past and geomagnetic paleointensities. Journal of Geodynamics 34 (5), 97–115.
Doglioni, C., Carminati, E., Cuffaro, M., Scrocca, D., 2007. Subduction kinematics and dynamic
constraints. Earth-Science Reviews 83, 125–175. doi:10.1016/j.earscirev.2007.04.001.
Doglioni, C., Tonarini, S., Innocenti, F., 2009. Mantle wedge asymmetries along opposite
subduction zones. Lithos 113, 179–189. doi:10.1016/j.lithos.2009.01.012.
Dziewonski, A.M., Anderson, D.L., 1981. Preliminary reference Earthmodel. PEPI 25, 297–356.
Frohlich, C., 2006. Deep Earthquakes. Cambridge University Press.
Giardini, D., Di Donato, M., Boschi, E., 1997. Calibration of magnitude scales for earthquakes
of the Mediterranean. Journal of Seismology 1, 161–180.
Green, H.W., 2007. Shearing instabilities accompanying high-pressure phase transformations
and the mechanics of deep earthquakes. Proceedings of the National Academy
of Sciences of the United States of America. doi:10.1073/pnas.0608045104.
Gutenberg, B., 1956a. The energy of earthquakes. Quarterly Journal of the Geological
Society of London 112, 1–14.Gutenberg, B., 1956b. Great earthquakes 1896–1903. Eos Trans. AGU 37, 608–614.
Gutenberg, B., Richter, C.F., 1936. Materials for the study of deep-focus earthquakes.
Bulletin of the Seismological Society of America 26 (4), 341–390.
Gutenberg, B., Richter, C.F., 1938. Depth and geographical distribution of deep-focus
earthquakes. GSA Bulletin 49 (1), 249–288.
Gutenberg, B., Richter, C.F., 1942. Earthquake magnitude, intensity, energy, and acceleration.
Bulletin of the Seismological Society of America 32, 163–191.
Gutenberg, B., Richter, C.F., 1954. Seismicity of the Earth, 2nd edition. Princeton University
Press.
Gutenberg, B., Richter, C.F., 1956. Earthquake magnitude, intensity, energy and acceleration
(second paper). Bulletin of the Seismological Society of America 46, 105–145.
Gutscher, M.-A.,Westbrook, G.K., 2009. Great earthquakes in slow-subduction, low-taper
margins. In: Lallemand, S., Funiciello, F. (Eds.), Subduction Zone Geodynamics. : Frontiers
in Earth Sciences. Springer-Verlag Berlin Heidelberg, pp. 119–133. doi:10.1007/
978-3-540-87974-9.
Herak, M., Panza, G.F., Costa, G., 2001. Theoretical and observed depth correction for
MS. Pure and Applied Geophysics 158, 1517–1530.
Kagan, Y.Y., 2003. Accuracy of modern global earthquake catalogs. PEPI 135, 173–209.
Kanamori, H., 1977. The energy release in great earthquakes. Journal of Geophysical
Research 82 (20), 2981–2987.
Kanamori, H., 1983. Magnitude scale and quantification of earthquakes. Tectonophysics
93 (3–4), 185–199.
Keilis-Borok, V.I., Knopoff, L., Rotwain, I.M., 1980. Burst of aftershocks, long-term precursors
of strong earthquakes. Nature 283 (5744), 259–263.
Kirby, S.H., Durham, W.B., Stern, L.A., 1991. Mantle phase changes and deepearthquake
faulting in subducting lithosphere. Science 252, 216–225.
Kirby, S.H., Stein, S., Okal, E.A., Rubie, D.C., 1996. Metastable mantle phase transformations
and deep earthquakes in subducting oceanic lithosphere. Reviews of Geophysics
34 (2), 261–306.
Kossobokov, V.G., 2004. Earthquake prediction: basics, achievements, perspectives.
Acta Geod. Geophys. Hung. 39 (2–3), 205–221.
Kossobokov, V.G., Romashkova, L.L., Keilis-Borok, V.I., Healy, J.H., 1999. Testing earthquake
prediction algorithms: statistically significant advance prediction of the
largest earthquakes in the Circum-Pacific, 1992–1997. Physics of the Earth and
Planetary Interiors 111, 187–196.
Levin, B.W., Chirkov, Ye.B., 2001. Planetary maxima of the earth seismicity. Physics and
Chemistry of the Earth, Part C 26 (10–12), 781–786.
Levin, B.W., Sasorova, E.V., 2009. Latitudinal distribution of earthquakes in the Andes
and its Peculiarity. Advances in Geosciences 22, 139–145.
Melosh, H.J., 1977. Global tectonics of a despun planet. Icarus 31, 221–243.
Molchan, G., Kronrod, T., Panza, G.F., 1997. Multi-scale seismicity model for seismic
risk. B.S.S.A. 87, 1220–1229.
Pacheco, J.F., Sykes, L.R., 1992. Seismic moment catalog of large shallow earthquakes,
1900 to 1989. BSSA 82 (3), 1306–1349.
Panza, G., Doglioni, C., Levshin, A., 2010. Asymmetric ocean basins. Geology 38 (1), 59–62.
Parsons, T., 2006. Tectonic stressing in California modeled from GPS observations. Journal
of Geophysical Research 111, B03407.
Richter, F.M., 1979. Focal mechanisms and seismic energy release of deep and intermediate
earthquakes in the Tonga–Kermadec region and their bearing on the depth
extent of mantle flow. Journal of Geophysical Research 84 (B12), 6783–6795.
Riguzzi, F., Panza, G., Varga, P., Doglioni, C., 2010. Can Earth's rotation and tidal despinning
drive plate tectonics? Tectonophysics 484 (1–4), 60–73.
Romashkova, L.L., 2009. Global-scale analysis of seismic activity prior to 2004 Sumatra-
Andaman mega-earthquake. Tectonophysics 470, 329–344.
Ruff, L., Kanamori, H., 1980. Seismicity and the subduction process. Physics of the Earth
and Planetary Interiors 23, 240–252.
Scholz, C.H., 2003. The Mechanics of Earthquakes and Faulting. Cambridge Univ. Press.
Shanker, D., Kapur, N., Singh, V.P., 2001. On the spatio temporal distribution of global
seismicity and rotation of the Earth — a review. Acta Geod. Geophys. Hung. 36
(2), 175–187.
Shebalin, P.N., 1992. Automatic duplicate identification in set of earthquake catalogs
merged together. U.S. Geol. Surv. Open-File Report 92–401 Appendix II.
Steacy, S., Gomberg, J., Cocco, M., 2005. Introduction to special section: stress transfer,
earthquake triggering, and time-dependent seismic hazard. Journal of Geophysical
Research 110, B05S01. doi:10.1029/2005JB003692.
Stein, S., Wysession, M., 2003. Introduction to Seismology, Earthquakes and Earth
Structure. Blackwell Publishing.
Sun, W., 1992. Seismic energy distribution in latitude and a possible tidal stress explanation.
Physics of the Earth and Planetary Interiors 71 (3–4), 205–216.
Utsu, T., 2002. Relationships between magnitude scales. In: Lee, W.H.K., Kanamori, H.,
Jennings, P.C., Kisslinger, C. (Eds.), International Handbook of Earthquake and Engineering
Seismology, Part A. Academic Press, Amsterdam, pp. 733–746.
Van der Hilst, R.D., 1995. Complex morphology of subducted lithosphere in the mantle
beneath the Tonga trench. Nature 374, 154–157.
Van Stiphout, T., Zhuang, J., Marsan, D., 2010. Seismicity Declustering, Community Online
Resource for Statistical Seismicity AnalysisAvailable at http://www.corssa.org2010.
Varga, P., 1995. Temporal variation of the figure of the Earth and seismic energy release.
Publication of the Institute of Geodesy and Navigation, University FAF, Munich,
pp. 118–127.
Venkataraman, A., Kanamori, H., 2004. Observational constraints on the fracture energy
of subduction zone earthquakes. Journal of Geophysical Research 109, B05302.
doi:10.1029/2003JB002549.
Zoback, M.L., 1992. First- and second-order patterns of stress in the lithosphere: the
World Stress Map Project. Journal of Geophysical Research 97 (B8), 11703–11728.
focus earthquakes. Journal of Geophysical Research 84, 3589–3595.
Amalvict,M., Legros,H., 1993. Stresses in the lithosphere induced by the Earth rotation. In:
Teisseyre, R. (Ed.), Physics and Evolution of the Earth's Interior, Volume 6: Dynamics
of the Earth's Evolution. PWNWarszawa and Elsevier, Amsterdam, pp. 348–349.
Bird, P., Kagan, Y.Y., Jackson, D.D., Shoenberg, F.P., Werner, M.J., 2009. Linear and nonlinear
relations between relative plate velocity and seismicity. Bulletin of the Seismological
Society of America 99 (6), 3097–3113.
Bormann, P., Saul, J., 2009. Earthquake magnitude. In: Meyers, R.A. (Ed.), Encyclopedia
on Complexity and Systems Science. Springer, Heidelberg.
Chouhan, R.K.S., Das, U.C., 1971. Preliminary report on global seismicity-frequency energy
distribution of earthquakes. Pure and Applied Geophysics 89 (1), 98–108.
Convers, J.A., Newman, A.V., 2011. Global evaluation of large earthquake energy from
1997 through mid-2010. Journal of Geophysical Research 116, B08304. doi:10.1029/
2010JB007928.
Crespi, M., Cuffaro, M., Doglioni, C., Giannone, F., Riguzzi, F., 2007. Space geodesy validation
of the global lithospheric flow. Geophysical Journal International 168,
491–506. doi:10.1111/j.1365-246X.2006.03226.
Denis, C., Schreider, A.A., Varga, P., Závoti, J., 2002. Despinning of the Earth rotation in the geological
past and geomagnetic paleointensities. Journal of Geodynamics 34 (5), 97–115.
Doglioni, C., Carminati, E., Cuffaro, M., Scrocca, D., 2007. Subduction kinematics and dynamic
constraints. Earth-Science Reviews 83, 125–175. doi:10.1016/j.earscirev.2007.04.001.
Doglioni, C., Tonarini, S., Innocenti, F., 2009. Mantle wedge asymmetries along opposite
subduction zones. Lithos 113, 179–189. doi:10.1016/j.lithos.2009.01.012.
Dziewonski, A.M., Anderson, D.L., 1981. Preliminary reference Earthmodel. PEPI 25, 297–356.
Frohlich, C., 2006. Deep Earthquakes. Cambridge University Press.
Giardini, D., Di Donato, M., Boschi, E., 1997. Calibration of magnitude scales for earthquakes
of the Mediterranean. Journal of Seismology 1, 161–180.
Green, H.W., 2007. Shearing instabilities accompanying high-pressure phase transformations
and the mechanics of deep earthquakes. Proceedings of the National Academy
of Sciences of the United States of America. doi:10.1073/pnas.0608045104.
Gutenberg, B., 1956a. The energy of earthquakes. Quarterly Journal of the Geological
Society of London 112, 1–14.Gutenberg, B., 1956b. Great earthquakes 1896–1903. Eos Trans. AGU 37, 608–614.
Gutenberg, B., Richter, C.F., 1936. Materials for the study of deep-focus earthquakes.
Bulletin of the Seismological Society of America 26 (4), 341–390.
Gutenberg, B., Richter, C.F., 1938. Depth and geographical distribution of deep-focus
earthquakes. GSA Bulletin 49 (1), 249–288.
Gutenberg, B., Richter, C.F., 1942. Earthquake magnitude, intensity, energy, and acceleration.
Bulletin of the Seismological Society of America 32, 163–191.
Gutenberg, B., Richter, C.F., 1954. Seismicity of the Earth, 2nd edition. Princeton University
Press.
Gutenberg, B., Richter, C.F., 1956. Earthquake magnitude, intensity, energy and acceleration
(second paper). Bulletin of the Seismological Society of America 46, 105–145.
Gutscher, M.-A.,Westbrook, G.K., 2009. Great earthquakes in slow-subduction, low-taper
margins. In: Lallemand, S., Funiciello, F. (Eds.), Subduction Zone Geodynamics. : Frontiers
in Earth Sciences. Springer-Verlag Berlin Heidelberg, pp. 119–133. doi:10.1007/
978-3-540-87974-9.
Herak, M., Panza, G.F., Costa, G., 2001. Theoretical and observed depth correction for
MS. Pure and Applied Geophysics 158, 1517–1530.
Kagan, Y.Y., 2003. Accuracy of modern global earthquake catalogs. PEPI 135, 173–209.
Kanamori, H., 1977. The energy release in great earthquakes. Journal of Geophysical
Research 82 (20), 2981–2987.
Kanamori, H., 1983. Magnitude scale and quantification of earthquakes. Tectonophysics
93 (3–4), 185–199.
Keilis-Borok, V.I., Knopoff, L., Rotwain, I.M., 1980. Burst of aftershocks, long-term precursors
of strong earthquakes. Nature 283 (5744), 259–263.
Kirby, S.H., Durham, W.B., Stern, L.A., 1991. Mantle phase changes and deepearthquake
faulting in subducting lithosphere. Science 252, 216–225.
Kirby, S.H., Stein, S., Okal, E.A., Rubie, D.C., 1996. Metastable mantle phase transformations
and deep earthquakes in subducting oceanic lithosphere. Reviews of Geophysics
34 (2), 261–306.
Kossobokov, V.G., 2004. Earthquake prediction: basics, achievements, perspectives.
Acta Geod. Geophys. Hung. 39 (2–3), 205–221.
Kossobokov, V.G., Romashkova, L.L., Keilis-Borok, V.I., Healy, J.H., 1999. Testing earthquake
prediction algorithms: statistically significant advance prediction of the
largest earthquakes in the Circum-Pacific, 1992–1997. Physics of the Earth and
Planetary Interiors 111, 187–196.
Levin, B.W., Chirkov, Ye.B., 2001. Planetary maxima of the earth seismicity. Physics and
Chemistry of the Earth, Part C 26 (10–12), 781–786.
Levin, B.W., Sasorova, E.V., 2009. Latitudinal distribution of earthquakes in the Andes
and its Peculiarity. Advances in Geosciences 22, 139–145.
Melosh, H.J., 1977. Global tectonics of a despun planet. Icarus 31, 221–243.
Molchan, G., Kronrod, T., Panza, G.F., 1997. Multi-scale seismicity model for seismic
risk. B.S.S.A. 87, 1220–1229.
Pacheco, J.F., Sykes, L.R., 1992. Seismic moment catalog of large shallow earthquakes,
1900 to 1989. BSSA 82 (3), 1306–1349.
Panza, G., Doglioni, C., Levshin, A., 2010. Asymmetric ocean basins. Geology 38 (1), 59–62.
Parsons, T., 2006. Tectonic stressing in California modeled from GPS observations. Journal
of Geophysical Research 111, B03407.
Richter, F.M., 1979. Focal mechanisms and seismic energy release of deep and intermediate
earthquakes in the Tonga–Kermadec region and their bearing on the depth
extent of mantle flow. Journal of Geophysical Research 84 (B12), 6783–6795.
Riguzzi, F., Panza, G., Varga, P., Doglioni, C., 2010. Can Earth's rotation and tidal despinning
drive plate tectonics? Tectonophysics 484 (1–4), 60–73.
Romashkova, L.L., 2009. Global-scale analysis of seismic activity prior to 2004 Sumatra-
Andaman mega-earthquake. Tectonophysics 470, 329–344.
Ruff, L., Kanamori, H., 1980. Seismicity and the subduction process. Physics of the Earth
and Planetary Interiors 23, 240–252.
Scholz, C.H., 2003. The Mechanics of Earthquakes and Faulting. Cambridge Univ. Press.
Shanker, D., Kapur, N., Singh, V.P., 2001. On the spatio temporal distribution of global
seismicity and rotation of the Earth — a review. Acta Geod. Geophys. Hung. 36
(2), 175–187.
Shebalin, P.N., 1992. Automatic duplicate identification in set of earthquake catalogs
merged together. U.S. Geol. Surv. Open-File Report 92–401 Appendix II.
Steacy, S., Gomberg, J., Cocco, M., 2005. Introduction to special section: stress transfer,
earthquake triggering, and time-dependent seismic hazard. Journal of Geophysical
Research 110, B05S01. doi:10.1029/2005JB003692.
Stein, S., Wysession, M., 2003. Introduction to Seismology, Earthquakes and Earth
Structure. Blackwell Publishing.
Sun, W., 1992. Seismic energy distribution in latitude and a possible tidal stress explanation.
Physics of the Earth and Planetary Interiors 71 (3–4), 205–216.
Utsu, T., 2002. Relationships between magnitude scales. In: Lee, W.H.K., Kanamori, H.,
Jennings, P.C., Kisslinger, C. (Eds.), International Handbook of Earthquake and Engineering
Seismology, Part A. Academic Press, Amsterdam, pp. 733–746.
Van der Hilst, R.D., 1995. Complex morphology of subducted lithosphere in the mantle
beneath the Tonga trench. Nature 374, 154–157.
Van Stiphout, T., Zhuang, J., Marsan, D., 2010. Seismicity Declustering, Community Online
Resource for Statistical Seismicity AnalysisAvailable at http://www.corssa.org2010.
Varga, P., 1995. Temporal variation of the figure of the Earth and seismic energy release.
Publication of the Institute of Geodesy and Navigation, University FAF, Munich,
pp. 118–127.
Venkataraman, A., Kanamori, H., 2004. Observational constraints on the fracture energy
of subduction zone earthquakes. Journal of Geophysical Research 109, B05302.
doi:10.1029/2003JB002549.
Zoback, M.L., 1992. First- and second-order patterns of stress in the lithosphere: the
World Stress Map Project. Journal of Geophysical Research 97 (B8), 11703–11728.
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